/*-----------------------------------------------------------------
 * Programmer(s): Daniel R. Reynolds @ SMU
 *---------------------------------------------------------------
 * SUNDIALS Copyright Start
 * Copyright (c) 2002-2025, Lawrence Livermore National Security
 * and Southern Methodist University.
 * All rights reserved.
 *
 * See the top-level LICENSE and NOTICE files for details.
 *
 * SPDX-License-Identifier: BSD-3-Clause
 * SUNDIALS Copyright End
 *---------------------------------------------------------------
 * Example problem:
 *
 * The following test simulates a brusselator problem from chemical
 * kinetics.  This is an ODE system with 3 components, Y = [u,v,w],
 * satisfying the equations,
 *    du/dt = a - (w+1)*u + v*u^2
 *    dv/dt = w*u - v*u^2
 *    dw/dt = (b-w)/ep - w*u
 * for t in the interval [0.0, 10.0], with initial conditions
 * Y0 = [u0,v0,w0].
 *
 * We have 3 different testing scenarios:
 *
 * Test 1:  u0=3.9,  v0=1.1,  w0=2.8,  a=1.2,  b=2.5,  ep=1.0e-5
 *    Here, all three components exhibit a rapid transient change
 *    during the first 0.2 time units, followed by a slow and
 *    smooth evolution.
 *
 * Test 2:  u0=1.2,  v0=3.1,  w0=3,  a=1,  b=3.5,  ep=5.0e-6
 *    Here, w experiences a fast initial transient, jumping 0.5
 *    within a few steps.  All values proceed smoothly until
 *    around t=6.5, when both u and v undergo a sharp transition,
 *    with u increaseing from around 0.5 to 5 and v decreasing
 *    from around 6 to 1 in less than 0.5 time units.  After this
 *    transition, both u and v continue to evolve somewhat
 *    rapidly for another 1.4 time units, and finish off smoothly.
 *
 * Test 3:  u0=3,  v0=3,  w0=3.5,  a=0.5,  b=3,  ep=5.0e-4
 *    Here, all components undergo very rapid initial transients
 *    during the first 0.3 time units, and all then proceed very
 *    smoothly for the remainder of the simulation.
 *
 * This file is hard-coded to use test 2.
 *
 * This program solves the problem with the DIRK method, using a
 * Newton iteration with the SUNDENSE dense linear solver, and a
 * user-supplied Jacobian routine.
 *
 * 100 outputs are printed at equal intervals, and run statistics
 * are printed at the end.
 *-----------------------------------------------------------------*/

/* Header files */
#include <arkode/arkode_arkstep.h> /* prototypes for ARKStep fcts., consts */
#include <math.h>
#include <nvector/nvector_serial.h> /* serial N_Vector types, fcts., macros */
#include <stdio.h>
#include <sundials/sundials_types.h>   /* def. of type 'sunrealtype' */
#include <sunlinsol/sunlinsol_dense.h> /* access to dense SUNLinearSolver      */
#include <sunmatrix/sunmatrix_dense.h> /* access to dense SUNMatrix            */

#if defined(SUNDIALS_EXTENDED_PRECISION)
#define GSYM "Lg"
#define ESYM "Le"
#define FSYM "Lf"
#else
#define GSYM "g"
#define ESYM "e"
#define FSYM "f"
#endif

/* User-supplied Functions Called by the Solver */
static int f(sunrealtype t, N_Vector y, N_Vector ydot, void* user_data);
static int Jac(sunrealtype t, N_Vector y, N_Vector fy, SUNMatrix J,
               void* user_data, N_Vector tmp1, N_Vector tmp2, N_Vector tmp3);

/* Private function to check function return values */
static int check_flag(void* flagvalue, const char* funcname, int opt);

/* Main Program */
int main(void)
{
  /* general problem parameters */
  sunrealtype T0     = SUN_RCONST(0.0);       /* initial time */
  sunrealtype Tf     = SUN_RCONST(10.0);      /* final time */
  sunrealtype dTout  = SUN_RCONST(1.0);       /* time between outputs */
  sunindextype NEQ   = 3;                     /* number of dependent vars. */
  int Nt             = (int)ceil(Tf / dTout); /* number of output times */
  int test           = 2;                     /* test problem to run */
  sunrealtype reltol = 1.0e-6;                /* tolerances */
  sunrealtype abstol = 1.0e-10;
  sunrealtype a, b, ep, u0, v0, w0;

  /* general problem variables */
  int flag;                  /* reusable error-checking flag */
  N_Vector y         = NULL; /* empty vector for storing solution */
  SUNMatrix A        = NULL; /* empty matrix for solver */
  SUNLinearSolver LS = NULL; /* empty linear solver object */
  void* arkode_mem   = NULL; /* empty ARKode memory structure */
  sunrealtype rdata[3];
  FILE* UFID;
  sunrealtype t, tout;
  int iout;
  long int nst, nst_a, nfe, nfi, nsetups, nje, nfeLS, nni, nnf, ncfn, netf;

  /* Create the SUNDIALS context object for this simulation */
  SUNContext ctx;
  flag = SUNContext_Create(SUN_COMM_NULL, &ctx);
  if (check_flag(&flag, "SUNContext_Create", 1)) { return 1; }

  /* set up the test problem according to the desired test */
  if (test == 1)
  {
    u0 = SUN_RCONST(3.9);
    v0 = SUN_RCONST(1.1);
    w0 = SUN_RCONST(2.8);
    a  = SUN_RCONST(1.2);
    b  = SUN_RCONST(2.5);
    ep = SUN_RCONST(1.0e-5);
  }
  else if (test == 3)
  {
    u0 = SUN_RCONST(3.0);
    v0 = SUN_RCONST(3.0);
    w0 = SUN_RCONST(3.5);
    a  = SUN_RCONST(0.5);
    b  = SUN_RCONST(3.0);
    ep = SUN_RCONST(5.0e-4);
  }
  else
  {
    u0 = SUN_RCONST(1.2);
    v0 = SUN_RCONST(3.1);
    w0 = SUN_RCONST(3.0);
    a  = SUN_RCONST(1.0);
    b  = SUN_RCONST(3.5);
    ep = SUN_RCONST(5.0e-6);
  }

  /* Initial problem output */
  printf("\nBrusselator ODE test problem:\n");
  printf("    initial conditions:  u0 = %" GSYM ",  v0 = %" GSYM
         ",  w0 = %" GSYM "\n",
         u0, v0, w0);
  printf("    problem parameters:  a = %" GSYM ",  b = %" GSYM ",  ep = %" GSYM
         "\n",
         a, b, ep);
  printf("    reltol = %.1" ESYM ",  abstol = %.1" ESYM "\n\n", reltol, abstol);

  /* Initialize data structures */
  rdata[0] = a; /* set user data  */
  rdata[1] = b;
  rdata[2] = ep;
  y        = N_VNew_Serial(NEQ, ctx); /* Create serial vector for solution */
  if (check_flag((void*)y, "N_VNew_Serial", 0)) { return 1; }
  NV_Ith_S(y, 0) = u0; /* Set initial conditions */
  NV_Ith_S(y, 1) = v0;
  NV_Ith_S(y, 2) = w0;

  /* Call ARKStepCreate to initialize the ARK timestepper module and
     specify the right-hand side function in y'=f(t,y), the initial time
     T0, and the initial dependent variable vector y.  Note: since this
     problem is fully implicit, we set f_E to NULL and f_I to f. */
  arkode_mem = ARKStepCreate(NULL, f, T0, y, ctx);
  if (check_flag((void*)arkode_mem, "ARKStepCreate", 0)) { return 1; }

  /* Set routines */
  flag = ARKodeSetUserData(arkode_mem,
                           (void*)rdata); /* Pass rdata to user functions */
  if (check_flag(&flag, "ARKodeSetUserData", 1)) { return 1; }

  flag = ARKodeSStolerances(arkode_mem, reltol, abstol); /* Specify tolerances */
  if (check_flag(&flag, "ARKodeSStolerances", 1)) { return 1; }

  flag = ARKodeSetInterpolantType(arkode_mem,
                                  ARK_INTERP_LAGRANGE); /* Specify stiff interpolant */
  if (check_flag(&flag, "ARKodeSetInterpolantType", 1)) { return 1; }

  flag = ARKodeSetDeduceImplicitRhs(arkode_mem, 1); /* Avoid eval of f after stage */
  if (check_flag(&flag, "ARKodeSetDeduceImplicitRhs", 1)) { return 1; }

  /* Initialize dense matrix data structure and solver */
  A = SUNDenseMatrix(NEQ, NEQ, ctx);
  if (check_flag((void*)A, "SUNDenseMatrix", 0)) { return 1; }

  LS = SUNLinSol_Dense(y, A, ctx);
  if (check_flag((void*)LS, "SUNLinSol_Dense", 0)) { return 1; }

  /* Linear solver interface */
  flag = ARKodeSetLinearSolver(arkode_mem, LS,
                               A); /* Attach matrix and linear solver */
  if (check_flag(&flag, "ARKodeSetLinearSolver", 1)) { return 1; }

  flag = ARKodeSetJacFn(arkode_mem, Jac); /* Set Jacobian routine */
  if (check_flag(&flag, "ARKodeSetJacFn", 1)) { return 1; }

  /* Signal that this problem does not explicitly depend on time. In this case
     enabling/disabling this option will lead to slightly different results when
     combined with ARKodeSetDeduceImplicitRhs because the implicit method is
     stiffly accurate. The differences are due to reuse of the deduced implicit
     RHS evaluation in the nonlinear residual. */
  flag = ARKodeSetAutonomous(arkode_mem, SUNTRUE);
  if (check_flag(&flag, "ARKodeSetAutonomous", 1)) { return 1; }

  /* Open output stream for results, output comment line */
  UFID = fopen("solution.txt", "w");
  fprintf(UFID, "# t u v w\n");

  /* output initial condition to disk */
  fprintf(UFID, " %.16" ESYM " %.16" ESYM " %.16" ESYM " %.16" ESYM "\n", T0,
          NV_Ith_S(y, 0), NV_Ith_S(y, 1), NV_Ith_S(y, 2));

  /* Main time-stepping loop: calls ARKodeEvolve to perform the integration, then
     prints results.  Stops when the final time has been reached */
  t    = T0;
  tout = T0 + dTout;
  printf("        t           u           v           w\n");
  printf("   -------------------------------------------\n");
  printf("  %10.6" FSYM "  %10.6" FSYM "  %10.6" FSYM "  %10.6" FSYM "\n", t,
         NV_Ith_S(y, 0), NV_Ith_S(y, 1), NV_Ith_S(y, 2));

  for (iout = 0; iout < Nt; iout++)
  {
    flag = ARKodeEvolve(arkode_mem, tout, y, &t, ARK_NORMAL); /* call integrator */
    if (check_flag(&flag, "ARKodeEvolve", 1)) { break; }
    printf("  %10.6" FSYM "  %10.6" FSYM "  %10.6" FSYM "  %10.6" FSYM
           "\n", /* access/print solution */
           t, NV_Ith_S(y, 0), NV_Ith_S(y, 1), NV_Ith_S(y, 2));
    fprintf(UFID, " %.16" ESYM " %.16" ESYM " %.16" ESYM " %.16" ESYM "\n", t,
            NV_Ith_S(y, 0), NV_Ith_S(y, 1), NV_Ith_S(y, 2));
    if (flag >= 0)
    { /* successful solve: update time */
      tout += dTout;
      tout = (tout > Tf) ? Tf : tout;
    }
    else
    { /* unsuccessful solve: break */
      fprintf(stderr, "Solver failure, stopping integration\n");
      break;
    }
  }
  printf("   -------------------------------------------\n");
  fclose(UFID);

  /* Print some final statistics */
  flag = ARKodeGetNumSteps(arkode_mem, &nst);
  check_flag(&flag, "ARKodeGetNumSteps", 1);
  flag = ARKodeGetNumStepAttempts(arkode_mem, &nst_a);
  check_flag(&flag, "ARKodeGetNumStepAttempts", 1);
  flag = ARKodeGetNumRhsEvals(arkode_mem, 0, &nfe);
  check_flag(&flag, "ARKodeGetNumRhsEvals", 1);
  flag = ARKodeGetNumRhsEvals(arkode_mem, 1, &nfi);
  check_flag(&flag, "ARKodeGetNumRhsEvals", 1);
  flag = ARKodeGetNumLinSolvSetups(arkode_mem, &nsetups);
  check_flag(&flag, "ARKodeGetNumLinSolvSetups", 1);
  flag = ARKodeGetNumErrTestFails(arkode_mem, &netf);
  check_flag(&flag, "ARKodeGetNumErrTestFails", 1);
  flag = ARKodeGetNumStepSolveFails(arkode_mem, &ncfn);
  check_flag(&flag, "ARKodeGetNumStepSolveFails", 1);
  flag = ARKodeGetNumNonlinSolvIters(arkode_mem, &nni);
  check_flag(&flag, "ARKodeGetNumNonlinSolvIters", 1);
  flag = ARKodeGetNumNonlinSolvConvFails(arkode_mem, &nnf);
  check_flag(&flag, "ARKodeGetNumNonlinSolvConvFails", 1);
  flag = ARKodeGetNumJacEvals(arkode_mem, &nje);
  check_flag(&flag, "ARKodeGetNumJacEvals", 1);
  flag = ARKodeGetNumLinRhsEvals(arkode_mem, &nfeLS);
  check_flag(&flag, "ARKodeGetNumLinRhsEvals", 1);

  printf("\nFinal Solver Statistics:\n");
  printf("   Internal solver steps = %li (attempted = %li)\n", nst, nst_a);
  printf("   Total RHS evals:  Fe = %li,  Fi = %li\n", nfe, nfi);
  printf("   Total linear solver setups = %li\n", nsetups);
  printf("   Total RHS evals for setting up the linear system = %li\n", nfeLS);
  printf("   Total number of Jacobian evaluations = %li\n", nje);
  printf("   Total number of Newton iterations = %li\n", nni);
  printf("   Total number of nonlinear solver convergence failures = %li\n", nnf);
  printf("   Total number of error test failures = %li\n", netf);
  printf("   Total number of failed steps from solver failure = %li\n", ncfn);

  /* Clean up and return with successful completion */
  N_VDestroy(y);           /* Free y vector */
  ARKodeFree(&arkode_mem); /* Free integrator memory */
  SUNLinSolFree(LS);       /* Free linear solver */
  SUNMatDestroy(A);        /* Free A matrix */
  SUNContext_Free(&ctx);   /* Free context */

  return 0;
}

/*-------------------------------
 * Functions called by the solver
 *-------------------------------*/

/* f routine to compute the ODE RHS function f(t,y). */
static int f(sunrealtype t, N_Vector y, N_Vector ydot, void* user_data)
{
  sunrealtype* rdata = (sunrealtype*)user_data; /* cast user_data to sunrealtype */
  sunrealtype a  = rdata[0];                    /* access data entries */
  sunrealtype b  = rdata[1];
  sunrealtype ep = rdata[2];
  sunrealtype u  = NV_Ith_S(y, 0); /* access solution values */
  sunrealtype v  = NV_Ith_S(y, 1);
  sunrealtype w  = NV_Ith_S(y, 2);

  /* fill in the RHS function */
  NV_Ith_S(ydot, 0) = a - (w + 1.0) * u + v * u * u;
  NV_Ith_S(ydot, 1) = w * u - v * u * u;
  NV_Ith_S(ydot, 2) = (b - w) / ep - w * u;

  return 0; /* Return with success */
}

/* Jacobian routine to compute J(t,y) = df/dy. */
static int Jac(sunrealtype t, N_Vector y, N_Vector fy, SUNMatrix J,
               void* user_data, N_Vector tmp1, N_Vector tmp2, N_Vector tmp3)
{
  sunrealtype* rdata = (sunrealtype*)user_data; /* cast user_data to sunrealtype */
  sunrealtype ep = rdata[2];                    /* access data entries */
  sunrealtype u  = NV_Ith_S(y, 0);              /* access solution values */
  sunrealtype v  = NV_Ith_S(y, 1);
  sunrealtype w  = NV_Ith_S(y, 2);

  /* fill in the Jacobian via SUNDenseMatrix macro, SM_ELEMENT_D (see sunmatrix_dense.h) */
  SM_ELEMENT_D(J, 0, 0) = -(w + 1.0) + 2.0 * u * v;
  SM_ELEMENT_D(J, 0, 1) = u * u;
  SM_ELEMENT_D(J, 0, 2) = -u;

  SM_ELEMENT_D(J, 1, 0) = w - 2.0 * u * v;
  SM_ELEMENT_D(J, 1, 1) = -u * u;
  SM_ELEMENT_D(J, 1, 2) = u;

  SM_ELEMENT_D(J, 2, 0) = -w;
  SM_ELEMENT_D(J, 2, 1) = 0.0;
  SM_ELEMENT_D(J, 2, 2) = -1.0 / ep - u;

  return 0; /* Return with success */
}

/*-------------------------------
 * Private helper functions
 *-------------------------------*/

/* Check function return value...
    opt == 0 means SUNDIALS function allocates memory so check if
             returned NULL pointer
    opt == 1 means SUNDIALS function returns a flag so check if
             flag >= 0
    opt == 2 means function allocates memory so check if returned
             NULL pointer
*/
static int check_flag(void* flagvalue, const char* funcname, int opt)
{
  int* errflag;

  /* Check if SUNDIALS function returned NULL pointer - no memory allocated */
  if (opt == 0 && flagvalue == NULL)
  {
    fprintf(stderr, "\nSUNDIALS_ERROR: %s() failed - returned NULL pointer\n\n",
            funcname);
    return 1;
  }

  /* Check if flag < 0 */
  else if (opt == 1)
  {
    errflag = (int*)flagvalue;
    if (*errflag < 0)
    {
      fprintf(stderr, "\nSUNDIALS_ERROR: %s() failed with flag = %d\n\n",
              funcname, *errflag);
      return 1;
    }
  }

  /* Check if function returned NULL pointer - no memory allocated */
  else if (opt == 2 && flagvalue == NULL)
  {
    fprintf(stderr, "\nMEMORY_ERROR: %s() failed - returned NULL pointer\n\n",
            funcname);
    return 1;
  }

  return 0;
}

/*---- end of file ----*/
